FI59468B - EXPANSIONSBULT - Google Patents

Description

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Sweden3i-Sverige (SE) U767 / 72 (71) (72) Karl Birger Sikström, Lilla Gränsgatan 2, S-971 00 Malmberget,

Sweden-Sverige (SE) (7U) Leitzinger Oy (5U) Expansion bolt - Expansionstmlt

The invention relates to an expansion bolt consisting of a clamping screw, a bearing cone rotating on it, having at least one outer wedge surface and a plurality of expansion spacers, each cooperating with its inner wedge surface or wedge surfaces on its inner wedge. is held on the cone by an elastic member, and the other end of the expansion spacers abuts the axial response of the screw when the expansion spacers are prevented from rotating and the screw is rotated to move the cone axially toward the stop while the expansion spacers are moved radially outward The displacement of the kei.den towards the wider end of the cone is limited to the end position where the axial response of the cone meets the axial of the expansion spacers. response.

Such expansion bolts are used e.g. in mines and are attached to holes drilled in the rock. After the spacers have been tightened against the wall of the hole, the bolt is usually securely anchored. However, the hole can sometimes be made in relatively loose or brittle rock types, and in such cases there may be certain difficulties. Namely, there is a danger that the walls of the hole 59468 may give up as long as the bolt has been anchored in the hole for some time. The size of the hole thus expands near the spacers and this can cause their adhesion to the hole to deteriorate. Under these conditions, in some commonly occurring expansion bolts, the cone and clamping screw move axially relative to the spacers as they are tightened to the relatively soft material of the hole wall, and at some position disengage contact with the spacers, pulling the clamping bolt and cone out of the hole. This, of course, poses a risk of accidents. For example, in the expansion bolt known from U.S. Pat. No. 3,227,031, stones and sand can enter the front of the abutment flange, preventing the bolt from operating.

The object of the present invention is to provide an expansion bolt of the type in question which is reliable and which can be securely anchored in holes, the walls of which give more or less up to the pressure caused by the expansion spacers. At the same time, the expansion bolt must be such that it can be mounted at any point inside a relatively deep hole, the depth of which can be several times greater than the length of the spacers.

To achieve these purposes, the expansion bolt according to the invention is characterized in that the inner side of the expansion spacers has an axial longitudinal groove, that the wide end of the cone is provided with a plurality of abutments arranged on its circumference, each guided in grooves in the expansion spacers. In this case, the abutment cams are well protected in the grooves, so that they are not subjected to shocks and deformations, and sand and rock chips cannot enter between the abutment surfaces.

A suitable embodiment of an expansion bolt according to the invention will now be described with reference to the accompanying drawings.

Figure 1 is a longitudinal section of the expansion bolt in its radial end position of the spacers.

Figure 2 is a side view of the bolt.

Figure 3 is a section along line 3-3 of Figure 1.

Figure 4 is a cross-sectional view taken along line 4-4 of Figure 1.

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Fig. 5 is the same longitudinal section as in Fig. 1, except that the cone is located against the stop of the clamping screw and the spacers are tightened to an intermediate position between the innermost position in the radial direction of the seals and the outermost position in the radial direction of the seals.

Figure 6 is a side view of the bolt of Figure 5.

Figure 7 is a cross-sectional view taken along line 7-7 of Figure 1.

In Figures 1 and 5, the tightening screw 10 is shown in section, omitting most of the length of the tightening screw, and only the inner threaded end 11 of the screw and its outer looped or other end 12 are shown. The total length of the screw can be several meters.

Screwed to the threaded end 11 of the screw 10 is a cone 13 consisting of two axially successive cones 14, 15. As can be seen in Figures 2, 3 and 4, the cross-section of these cones is octagonal so that the cones have eight flat wedge surfaces 16 respectively.

Each axially successive pair of wedge surfaces 16, 17 cooperates with corresponding flat, axially successive wedge surfaces 18, 19 in the expansion spacer 20. As can be seen in Figures 3 and 4, there are eight such expansion spacers around the cone 13.

These eight expansion spacers 20 are held against the cone 13 by means of two flexible members made of flexible material, which are rings 21 and 22 made of flexible material.

Every second wedge surface 19 of these eight flat wedge surfaces 19 cooperating with the cone 15 has an axial groove 23, the other end of which is formed as a substantially radial end surface intended to form a abutment surface for the cam 25 forming a radial protrusion on each other wedge surface 17 at the wider end of the cone 15. Each cam 25 has a radial end surface 25a which forms a abutment surface which, under certain conditions, is intended to co-operate with the abutment surface 24 at the end of the groove 23, as described below.

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The screw 10 is furthermore provided with an axial stop in the form of two washers 27, 28, against which the other end of the spacers 20 rests, as can be seen in Figures 1 and 5.

The spacers 20 may preferably be made of plastic.

When the expansion body consisting of spacers 20 is in its initial position according to Fig. 1, the expansion bolt can be inserted into a drilled hole with a larger diameter than the expansion body. The depth of the hole can be several times greater than the length of the spacers. Once the bolt has been brought to the desired depth, place the expansion piece slightly on the edge so that the spacers engage the walls of the hole. When the screw 10 is then rotated, the spacers engage the walls of the hole and thus prevent it from turning. The cone 13 is also effectively prevented from rotating with respect to the spacers because its flat wedge surfaces 16, 17 are in contact with the corresponding flat wedge surfaces 18, 19 of the spacers 20. The threaded end 11 of the screw 10 is thus screwed relative to the threads of the cone 13, whereby in this relative screw movement the cone moves towards the stops 27, 28, whereby the cone presses the spacers in the radial direction and compresses them radially outwards. However, the spacers cannot move in the axial direction because they lie against the stops 27, 28. In the case of a relatively loose rock type, it may happen that the spacers 20 are tensioned to the intermediate position shown in Fig. 5, where the other end of the cone 13 is against the stops 27, 28. If the diameter of the hole in the stone is only slightly larger than the expansion piece in its radial inner position according to Figure 1 and the rock type is so loose that the expansion piece can be tensioned to the position shown in Figure 5, this means that the bore 20 is correspondingly widened. If the spacers are relatively deep inside the borehole, a very good anchorage is obtained.

Should the expansion bolt now be subjected to undesired higher loads or vibrations, the walls of the hole could potentially give even more. This means that the spacers are located substantially axially in place in the borehole, while the screw 10 with its cones 13 moves axially relative to the spacers. This is made possible by a predetermined distance A, i.e. a clearance between the abutment surfaces 26, 24, as shown in FIG. During this relative axial displacement, the spacers 59468 thus tighten even more, increasing the diameter of the expansion piece and thus the adhesion of the spacers in the borehole. Once the relative axial displacement has occurred to such an extent that the abutment surfaces 26, 24 are in contact with each other, the screw 10 and the cone 13 can no longer be displaced relative to the spacers 20. The cams 25 thus act in this position as a stop cam, certainly preventing the screw and cone from being pulled out of the expansion body formed by the spacers 20. Instead, this expansion body now forms a relatively large diameter anchoring body locked to the screw, and this anchoring body is in the expanded part of the borehole at a point normally located relatively deep from the borehole opening. The expansion bolt according to the invention is thus anchored very reliably in the drilled holes, even when these are in relatively loose rock types.

If desired, the expansion body may consist of two axially spaced and axially separate groups of spacers, one group having wedge surfaces 18 and the other wedge surfaces 19 and grooves 23 therein. These two groups of spacers may optionally be separated by an axially spaced sleeve. When the axially separated spacer groups are arranged in this way, both groups can be formed with each other on wedge surfaces with different slopes. When the groups have different initial positions, the expansion bodies formed by these two spacer groups expand differently at both ends if desired.

The expansion bolt according to the invention also has some special advantages when attached to a hole in a hard rock type. If the hole is so large that the bolt only engages when the cone is close to or located against the stops 27, 28, according to the invention the safety is further increased if the bolt is pulled by hand, i. with a relatively small force in relation to the forces which can be produced by the traction units. When the bolt is now loaded with axial traction forces, the stronger the person pulls the bolt, the stronger the spacers will be pressed against the walls of the hole. Since the spacers are expediently made of a somewhat flexible plastic, the outer sides of the spacers are pressed elastically against the wall of the hole and conform to its surface, and at the same time a high frictional force is produced. This will make the bolt fit quite firmly.

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The cross-section of the cones 14, 15 is shown as octagonal, in which case they have eight flat wedge surfaces, but the number of flat wedge surfaces can also be something else. A circular cross-section is also possible, although less suitable.

The expansion bolt according to the invention can be used without disadvantages in holes with different diameters and in a relatively large diameter range, the size of which depends on the wedge angle of the wedge surfaces and the length and distance A between the abutment surfaces. Some known expansion bolts allow only a few mm variations in the hole, while the expansion bolt according to the invention, when the diameter of the expansion body is about 40 mm in its inner position, can be used in the form shown for holes with a diameter between 41 and 55 mm.

Claims (1)

7 59468 Claim An expansion bolt consisting of a clamping screw (10), a cone (13) rotatably mounted thereon, having at least one. an outer wedge surface (16, 17) and a plurality of expansion spacers (20) each cooperating on their inner wedge surface (18, 19) with the outer wedge surface or wedge surfaces, the expansion spacers being held on the cone by an elastic member (21, 22), and the other end of the expansion means rests against the axial on the screw. stop (27, 28) when the expansion spacers are prevented from rotating and the screw is rotated to move the cone axially towards the stop (27, 28) at the same time as the expansion spacers are moved radially outwards by the interaction of the wedge surfaces (16, 17; 18, 19), the transition to the wider end of the cone is limited to the end position where the axial stop (25, 25a) of the cone meets the axial stop (24) on the expansion spacers, characterized in that the inner side of the expansion spacers (20) has an axial longitudinal groove (23) abutments (25) arranged evenly on the circumference, each of which is guided in grooves (23) in the expansion spacers.